Kosuke Minamihata scite author profile

Protein modification methods represent fundamental techniques that are applicable in many fields. In this study, a site-specific protein cross-linking based on the oxidative tyrosine coupling reaction was demonstrated. In the presence of horseradish peroxidase (HRP) and H(2)O(2), tyrosine residues undergo one-electron oxidation reactions and form radicals in their phenolic moieties, and these species subsequently react with each other to form dimers or further react to generate polymers. Here, a peptide-tag containing a tyrosine residue(s) (Y-tag, of which the amino acid sequences were either GGGGY or GGYYY) was genetically introduced at the C-terminus of a model protein, Escherichia coli alkaline phosphatase (BAP). Following the incubation of recombinant BAPs with HRP and H(2)O(2), Y-tagged BAPs were efficiently cross-linked with each other, whereas wild-type BAP did not undergo cross-linking, indicating that the tyrosine residues in the Y-tags were recognized by HRP as the substrates. To determine the site-specificity of the cross-linking reaction, the Y-tag was selectively removed by thrombin digestion. The resultant BAP without the Y-tag showed no reactivity in the presence of HRP and H(2)O(2). Conversely, Y-tagged BAPs cross-linked by HRP treatment were almost completely digested into monomeric BAP units following incubation with the protease. Moreover, cross-linked Y-tagged BAPs retained ∼95% of their native enzymatic activity. These results show that HRP catalyzed the site-specific cross-linking of BAPs through tyrosine residues positioned in the C-terminal Y-tag. The site-selective enzymatic oxidative tyrosine coupling reaction should offer a practical option for site-specific and covalent protein modifications.

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Protein Heteroconjugation by the Peroxidase-Catalyzed Tyrosine Coupling Reaction

Minamihata

Goto

Kamiya

2011

Bioconjugate Chem.

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Combining different proteins can integrate the functions of each protein to produce novel protein conjugates with wider ranges of applications. We have previously introduced a peptide containing tyrosine residues (Y-tag) at the C-terminus of Escherichia coli alkaline phosphatase (BAP). The tyrosine residues in the Y-tag were efficiently recognized by horseradish peroxidase (HRP) and were site-specifically cross-linked with each other to yield BAP homoconjugates. In this study, the HRP-catalyzed tyrosine coupling reaction was used for protein heteroconjugation. Streptavidin (SA) was selected as the conjugation partner for BAP. The Y-tag (GGGGY) was genetically introduced to the C-terminus of SA. Prior to heteroconjugation, the reactivity of the Y-tagged SA was examined. The Y-tagged SA cross-linked to form an SA homoconjugate upon HRP treatment, whereas wild-type SA remained essentially intact. In the heteroconjugation reaction of BAP and SA, the Y-tagged BAP and SA were efficiently cross-linked with each other upon HRP treatment. The functions of the BAP-SA conjugates were evaluated by measuring the BAP enzymatic activity on a biotin-coated plate. The BAP-SA conjugate tethered to the plate showed BAP enzymatic activity, indicating that both BAP and SA retained their functions following heteroconjugation. The BAP-SA conjugate prepared from both Y-tagged BAP and SA showed the highest enzymatic activity on the biotin-coated plates. This result illustrates the advantage of the protein conjugation reaction in which multiple numbers of proteins can be conjugated at the same time.

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Enzymatic preparation of a redox-responsive hydrogel for encapsulating and releasing living cells

et al. 2014

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Self-assembly of Ni-NTA-modified β-annulus peptides into artificial viral capsids and encapsulation of His-tagged proteins

et al. 2016

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β-Annulus peptides bearing Cys at the N-terminal from tomato bushy stunt virus were synthesised using a standard Fmoc-protected solid-phase method, and the peptide was modified with Ni-NTA at the N-terminal. The Ni-NTA-modified β-annulus peptide self-assembled into virus-like nanocapsules of approximately 40 nm in diameter. The critical aggregation concentration of these nanocapsules in 10 mM Tris-HCl buffer (pH 7.3) at 25 °C was 0.053 μM, which is 470 times lower than that of unmodified β-annulus peptides. Moreover, size exclusion chromatography of the peptide assembly indicated encapsulation of His-tagged green fluorescent protein in the Ni-NTA-modified artificial viral capsid.

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